Exercise 2: Planar Intersections + Folding...step in the process, else, osculating planes will...

Planar Intersections + Folding

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Planar Intersections + Folding

Given a planar spatial entity, use an intersecting plane to inscribe line segments on the faces. Following the methods described in exercise 1, trace these line segments through all projections, and ultimately into the true shapes of the plane figures. These intersection lines can be conceived as ‘fold lines’ in the object.

The resulting spatial entity has been split at the intersecting plane, with one half mirrored across the plane. The actual spatial fold (ridge curve, in general terms) naturally sits entirely on the intersecting plane, which is called the osculating plane of the ridge.

The process can be repeated with multiple planes (and therefore folds), so long as the resulting form is rigorously traced and considered at each step in the process, else, osculating planes will produce object self-intersections and other difficulties.

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given a planar spatial entity, use an intersecting plane to inscribe line segments on the faces. following the methods described in exercise 1, trace these line segments through all projections, and ultimately into the true shapes of the plane figures. these intersection lines can be conceived as “fold lines” in the object.

the resulting spatial entity has been split at the intersecting plane, with one half mirrored across the plane. the actual spatial fold (ridge curve, in general terms) naturally sits entirely on the intersecting plane, which is called the osculating plane of the ridge.

The process can be repeated with multiple planes (and therefore folds), so long as the resultant form is rigorously traced and considered at each step in the process. else, osculating planes will produce object self-intersections and other difficulties.

planar intersections + folding

step 1: define four adjoined oblique plane figures [+ their true shapes]STEP 1: DEFINE FOUR ADJOINING OBLIQUE PLANE FIGURES (+ THEIR TRUE SHAPES)

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STEP 2: DEFINE AN INTERSECTING PLANE - USING A SPECIAL CASE RAMP PLANE, FROM EDGE VIEWstep 2: define an intersection plane - using a special case ramp plane, from edge view

step 3: inscribe lines of intersection on plane figures [+ on their true shape projections]

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STEP 3: INSCRIBE LINES OF INTERSECTION ON PLANE FIGURES (+ ON THEIR TRUE SHAPE PROJECTIONS)

step 2: define an intersection plane - using a special case ramp plane, from edge view

step 3: inscribe lines of intersection on plane figures [+ on their true shape projections]

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ASIDE: THE RESULTING SPATIAL ENTITY HAS BEEN SPLIT AT THE INTERSECTING PLANE, WITH

ONE HALF MIRRORED ACROSS THE PLANE, PRODUCING A FOLD

aside: the resulting spatial entity has been split at the intersecting plane, with one half mirrored across the plane, producing a fold

step 4: in the vertical projection, reflect all points and lines across the intersection line

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STEP 4: IN THE VERTICAL PROJECTION, REFLECT ALL POINTS AND LINES ACROSS THE INTERSECTION LINE

aside: the resulting spatial entity has been split at the intersecting plane, with one half mirrored across the plane, producing a fold

step 4: in the vertical projection, reflect all points and lines across the intersection line

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STEP 5: IN THE HORIZONTAL PROJECTION, POINT LOCATIONS RETAIN THEIR DISTANCE FROM THE AXISstep 5: in the horizontal projection, point locations retain their distance from the axis

step 6: connect the translated points in the horizontal projection

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STEP 6: CONNECT THE TRANSLATED POINTS IN THE HORIZONTAL PROJECTION

step 5: in the horizontal projection, point locations retain their distance from the axis

step 6: connect the translated points in the horizontal projection

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NOTE: THIS PROCESS ALWAYS PRODUCES A VALID SPATIAL OBJECT, BUT DOES NOT GUARANTEE IT WILL NOT SELF-INTERSECTnote: this process always produces a valid spatial object, but does not guarantee it will not self-intersect

final spatial object and drawing [excludes descriptions of true shapes]

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FINAL SPATIAL OBJECT AND DRAWING (EXCLUDES DESCRIPTIONS OF TRUE SHAPES)

note: this process always produces a valid spatial object, but does not guarantee it will not self-intersect

final spatial object and drawing [excludes descriptions of true shapes]

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4.105 Geometric Disciplines and Architecture Skills: Reciprocal MethodologiesFall 2012 For information about citing these materials or our Terms of Use, visit: http://ocw.mit.edu/terms.